Signal transmission apparatus

ABSTRACT

A signal transmission apparatus provided in the present invention, comprising: a substrate, and a Bluetooth antenna and WIFI antennas which are provided on the same side edge of the substrate. At least two branches of WIFI antennas are provided, and the Bluetooth antenna and the WIFI antennas are provided at intervals. According to the present invention, the Bluetooth antenna and the WIFI antennas are provided on the same side edge of the substrate, and the Bluetooth antenna and the WIFI antennas are provided at intervals, so that all the antennas of the signal transmission apparatus are provided at the edge of a terminal board, thereby facilitating signal transmission, and solving the problem in the prior art that the Bluetooth antenna and the WIFI antennas are respectively provided on two side edges of the substrate so as to affect data transmission.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present disclosure claims priority to Chinese invention No. 2020103924 08.3, filed on May 11, 2020, titled “SIGNAL TRANSMISSION APPARATUS”, which is incorporated by reference in the present disclosure in its entirety.

FIELD OF INVENTION

The present disclosure relates to a technical field of antennas, and especially to a signal transmission apparatus.

BACKGROUND OF INVENTION

At present, there are more and more multi-antenna systems, and the multi-antenna systems generally comprise a BLUETOOTH antenna and WI-FI antennas. An existing BLUETOOTH antenna is provided on a broad side edge of a substrate, while the WI-FI antennas are provided on another broad side edge of the substrate. However, when an antenna module is placed on a terminal board, it needs to be as close to an edge as possible, so that an effect of transmitting signals of an antenna is better. Therefore, antennas in the prior art are provided on two side edges, and the antenna on one side edge must be farther from an edge, affecting data transmission.

Therefore, the prior art has defects and needs to be improved and developed.

SUMMARY OF INVENTION

A technical problem to be solved by the present disclosure is to provide a signal transmission apparatus in view of above-mentioned defects in the prior art, aiming to solve a problem in the prior art that a BLUETOOTH antenna and WI-FI antennas are respectively provided on two side edges of a substrate, which affects data transmission.

A technical solution adopted by the present disclosure to solve the technical problem is as follows:

a signal transmission apparatus, wherein comprises: a substrate, and a BLUETOOTH antenna and WI-FI antennas which are provided on a same side edge of the substrate; at least two branches of the WI-FI antennas are provided, and the BLUETOOTH antenna and the WI-FI antennas are provided at intervals.

Further, the BLUETOOTH antenna is a magnetic current source BLUETOOTH antenna, and the WI-FI antennas are current source WI-FI antennas.

Further, the WI-FI antennas are configured with two branches, which are a first WI-FI antenna and a second WI-FI antenna respectively, and the BLUETOOTH antenna is arranged between the first WI-FI antenna and the second WI-FI antenna.

Further, the substrate is provided with a circuit ground, a first WI-FI antenna RF ground, and a second WI-FI antenna RF ground; the BLUETOOTH antenna is arranged on the circuit ground, the first WI-FI antenna is arranged on the first WI-FI antenna RF ground, and the second WI-FI antenna is arranged on the second WI-FI antenna RF ground.

Further, a first dividing slit is defined between the circuit ground and the first WI-FI antenna RF ground, and a second dividing slit is defined between the circuit ground and the second WI-FI antenna RF ground.

Further, widths of the first dividing slit and the second dividing slit are greater than or equal to 0.1 mm.

Further, microstrip transmission lines are arranged in the substrate, a circuit module is arranged on the circuit ground, and both the first WI-FI antenna and the second WI-FI antenna are connected to the circuit module through the microstrip transmission lines.

Further, a routing mode of the microstrip transmission lines is vertical routing or parallel routing.

Further, the magnetic current source BLUETOOTH antenna is a microstrip magnetic current source BLUETOOTH antenna and has a radiation slit.

Further, the WI-FI antennas are configured as vertical polarization antennas.

Further, the substrate is an FR4 substrate.

Further, the substrate is a hollow cuboid, and the BLUETOOTH antenna and the WI-FI antennas are arranged in the substrate and are close to a same long side edge.

Further, the widths of the first dividing slit and the second dividing slit are both configured to be 1 mm.

Further, the microstrip transmission lines are CPW transmission lines.

Further, the first dividing slit and the second dividing slit are formed by etching slits.

Further, a length of the radiation slit is greater than a half of a wavelength of a medium.

The signal transmission apparatus provided in the present disclosure comprises: the substrate, and the BLUETOOTH antenna and the WI-FI antennas which are provided on the same side edge of the substrate. At least two branches of the WI-FI antennas are provided, and the BLUETOOTH antenna and the WI-FI antennas are provided at intervals. According to the present disclosure, the BLUETOOTH antenna and the WI-FI antennas are provided on the same side edge of the substrate, and the BLUETOOTH antenna and the WI-FI antennas are provided at intervals, so that all the antennas of the signal transmission apparatus are provided at the edge of the terminal board, thereby facilitating signal transmission and solving the problem in the prior art that the BLUETOOTH antenna and the WI-FI antennas are respectively provided on the two side edges of the substrate, which affects data transmission.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a perspective diagram of a preferred embodiment of a signal transmission apparatus in the present disclosure.

FIG. 2 is a perspective diagram of another preferred embodiment of the signal transmission apparatus in the present disclosure.

FIG. 3 is an isolation degree parameter diagram of a WI-FI antenna and BLUETOOTH antennas in the preferred embodiment of the signal transmission apparatus in the present disclosure.

FIG. 4 is an omnidirectional horizontal radiation diagram of the WI-FI antennas in the preferred embodiment of the signal transmission apparatus in the present disclosure.

FIG. 5 is a radiation direction diagram of the BLUETOOTH antenna in the preferred embodiment of the signal transmission apparatus in the present disclosure.

FIG. 6 is a VSWR characteristic diagram of the WI-FI antennas and the BLUETOOTH antenna in the preferred embodiment of the signal transmission apparatus in the present disclosure.

DESCRIPTION OF REFERENCE NUMBERS

-   10, substrate; 20, BLUETOOTH antenna; 30, WI-FI antenna; 40, circuit     ground; 41, circuit board; 50, first WI-FI antenna RF ground; 60,     second WI-FI antenna RF ground; 70, first dividing slit; 80, the     second dividing slit; 90, microstrip transmission line.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

In order to make the objections, technical solutions, and effects of the present disclosure clearer and clearer, the present disclosure will be further described in detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are only used to explain the present disclosure, but not to limit the present disclosure.

An existing BLUETOOTH antenna is provided on one broad side edge of a substrate, and two branches of WI-FI antennas are arranged on another broad side edge of the substrate, so the BLUETOOTH antenna and the WI-FI antennas are distanced to a maximum extent; an antenna module needs to be placed as close to an edge as possible when it is placed on a terminal board to have a better effect of transmitting signals of an antenna; however, antennas in the prior art are distributed on two side edges, and the antenna on one side edge must be farther from an edge, affecting data transmission. The present disclosure solves this problem; in the present disclosure, all BLUETOOTH antenna and WI-FI antennas are provided on a same side edge of the substrate, so that when the signal transmission apparatus is installed on the terminal board, the side edge where the BLUETOOTH antenna and the WI-FI antennas are installed is assembled to the edge, thereby facilitating signal transmission.

Please refer to FIG. 1 and FIG. 2 , a signal transmission apparatus provided in the present disclosure comprises: a substrate 10, and a BLUETOOTH antenna 20 and WI-FI antennas 30 provided on the substrate 10; the BLUETOOTH antenna 20 and the WI-FI antennas 30 are provided on a same side edge of the substrate 10. At least two branches of WI-FI antennas 30 are provided, and the BLUETOOTH antenna 20 and the WI-FI antennas 30 are provided at intervals. The BLUETOOTH antenna 20 is arranged between the WI-FI antennas 30. If more than two of the WI-FI antennas 30 are provided, for example, three of the WI-FI antennas 30 are provided, then one of the WI-FI antennas 30 is provided on one side of the BLUETOOTH antenna 20, and two of the WI-FI antennas 30 are provided on another side of the BLUETOOTH antenna 20. Two adjacent WI-FI antennas 30 are also arranged at intervals to improve an isolation degree.

Specifically, the substrate 10 is a hollow cuboid, the BLUETOOTH antenna 20 and the WI-FI antennas 30 are arranged in the substrate 10 and are close to a same long side edge. In this way, the antennas of the signal transmission apparatus can be arranged on an edge of the terminal board, thereby facilitating signal transmission and solving the problem in the prior art that the BLUETOOTH antenna and the WI-FI antennas are respectively provided on two side edges of the substrate, which affects data transmission. Moreover, in the present disclosure, all the antennas are arranged on the long side edge of the substrate, compared with all the antennas arranged on the broad side edge of the substrate, which is advantageous to isolation between the antennas in terms of the distance.

Further, in a field of the antennas, a certain isolation degree is often required between multiple antennas. However, when multiple antenna systems are integrated into one module, a spatial distance of the antennas is small, and it is very difficult to improve the isolation degree. In a design that the WI-FI antennas and the BLUETOOTH (BT) antenna share a same module and are integrated, the isolation degree between individual antennas is often achieved by distancing the antennas. For example, considering that a requirement of the isolation degree between the WI-FI antennas and the BLUETOOTH antenna is high, while a requirement of isolation degree between the WI-FI antennas is relatively low, the BLUETOOTH antenna is placed on one side edge of the substrate, and the two WI-FI antennas are placed on another side edge of a circuit board to distance to a maximum extent.

When the above methods are actually used, a target isolation state cannot be achieved between the individual antennas. A main reason is that a shortest wavelength of an antenna carrier signal is 12 cm, and co-frequency isolation must reach more than −30 dB, and a spatial distance must reach more than two wavelengths. Completely adopting a spatial isolation method will increase a volume of the integrated antenna module, and it is difficult to realize a miniaturization of the antenna module.

In addition, the spatial isolation method is currently used to improve the isolation degree; when arranging, the two WI-FI antennas are basically arranged in parallel, while an orientation of the BLUETOOTH antenna is orthogonal to the WI-FI antennas, in order to achieve polarization orthogonal isolation. However, because the three antennas share a same circuit ground, antenna radiation is not only the antenna itself, but also the circuit board connected thereto, so a polarization isolation effect is also limited.

A fundamental reason for above isolation results is that the antennas used in the existing multiple antenna modules are all current source antennas, that is, the existing BLUETOOTH antenna and the WI-FI antennas are all current source antennas. Then, it is difficult to realize orthogonal polarization between the two types of the antennas, thereby realizing the polarization isolation.

Therefore, the BLUETOOTH antenna 20 is arranged as a magnetic current source BLUETOOTH antenna in the present disclosure, and the WI-FI antennas 30 are arranged as current source WI-FI antennas. A radiation source of the magnetic current source BLUETOOTH antenna is a magnetic current source, and a radiation source of the current source WI-FI antennas is a current source, and both are arranged at intervals; that is, the magnetic current source BLUETOOTH antenna is always arranged between the current source WI-FI antennas. In this way, the orthogonal polarization is achieved by using the antennas with different radiation sources in an interaction direction, thereby achieving polarization isolation. At the same time, an RF ground of the BLUETOOTH antenna 20 has an isolation function, and the isolation degree between the WI-FI antennas 30 is also significantly improved. That is to say, an RF ground of the magnetic current source is arranged between the WI-FI antennas to achieve isolation between the WI-FI antennas. The isolation degree between the WI-FI antennas can be significantly improved, thereby reducing a possibility of using spatial isolation and meeting a requirement of module miniaturization.

In an embodiment, two branches of the WI-FI antennas 30 are provided, which are a first WI-FI antenna and a second WI-FI antenna, and the BLUETOOTH antenna 20 is arranged between the first WI-FI antenna and the second WI-FI antenna. Specifically, in the present disclosure, a magnetic current source antenna is provided as the BLUETOOTH antenna 20, two current source vertical polarization antennas are provided as the WI-FI antennas 30, and the two WI-FI antennas 30 are located on both sides of the BLUETOOTH antenna 20 to realize the polarization isolation between the BLUETOOTH antenna 20 and the WI-FI antennas 30. At the same time, an RF ground of the magnetic current source antenna has an isolation effect on RF grounds of the two WI-FI antennas 30, and the isolation degree between the two WI-FI antennas 30 can be significantly improved.

Since the two WI-FI antennas 30 and the one BLUETOOTH antenna 20 in the prior art are arranged on the circuit board, all the RF grounds of the three antennas are the circuit ground 40; that is, the two WI-FI antennas 30 and the one BLUETOOTH antenna 20 have the common RF ground, which greatly reduces effects of various isolation methods. In order to solve the above problems, the present disclosure no longer only arranges the circuit ground in the substrate 10, the circuit ground is a PCB board, but arranges the circuit ground 40, a first WI-FI antenna RF ground 50, and a second WI-FI antenna RF ground 60 in the substrate 10. The BLUETOOTH antenna 20 is arranged on the circuit ground 40, the first WI-FI antenna is arranged on the first WI-FI antenna RF ground 50, and the second WI-FI antenna is arranged on the second WI-FI antenna RF ground 60 to prevent the two WI-FI antennas 30 and the one BLUETOOTH antenna 20 from having the same RF ground to reduce the isolation degree.

Further, a first dividing slit 70 is defined between the circuit ground 40 and the first WI-FI antenna RF ground 50, and a second dividing slit 80 is defined between the circuit ground 40 and the second WI-FI antenna RF ground 60. That is to say, the circuit ground 40, the first WI-FI antenna RF ground 50, and the second WI-FI antenna RF ground 60 are independently arranged. Specifically, the RF grounds where the WI-FI antennas 30 are located in the present disclosure separate the first WI-FI antenna RF ground 50 and the second WI-FI antenna RF ground 60 from the circuit ground 40 by etching slits on the PCB board. The isolation of the slits of the antenna RF ground causes the multiple antennas share the same circuit board but does not share the same ground. By controlling a direction of an RF current, polarization characteristics of radiation are controlled. That is to say, the first WI-FI antenna RF ground 50 and the second WI-FI antenna RF ground 60 are both separated from the circuit ground 40 with the dividing slits, so that the three grounds have no direct connection among them, and there is no possibility of indirect coupling, which overcomes a problem that the effects of various isolation methods are greatly reduced due to the common RF ground among the multiple antennas. When more than two of the WI-FI antennas 30 are provided, for example, three of the WI-FI antennas 30 are provided, then one of the WI-FI antennas 30 is provided on one side of the BLUETOOTH antenna 20, and two of the WI-FI antennas 30 are provided on another side of the BLUETOOTH antenna 20. A dividing slit is also defined between the RF grounds of two adjacent WI-FI antennas 30 to improve the isolation degree.

Further, widths of the first dividing slit 70 and the second dividing slit 80 are greater than or equal to 0.1 mm. In an embodiment, the widths of the first dividing slit 70 and the second dividing slit 80 are configured to be about 1 mm. That is to say, each of the first WI-FI antenna RF ground 50 and the second WI-FI antenna RF ground 60 has a slit of about 1 mm from the circuit ground 40. Specifically, each of the widths of the first dividing slit 70 and the second dividing slit 80 is configured to be 1 mm.

Further, a microstrip transmission line 90 is arranged in the substrate 10, a circuit module is arranged on the circuit ground 40, and both the first WI-FI antenna 30 and the second WI-FI antenna 30 are connected to the circuit module through the microstrip transmission line 90, thereby performing data transmission.

Further, a routing mode of the microstrip transmission line 90 is vertical routing or parallel routing. That is to say, the microstrip transmission line 90 (i.e., an RF transmission line) is an orthogonal routing layout, and an orthogonal layout of the vertical routing and the horizontal routing are arranged to ensure that a polarization mode of the antenna is not affected, thereby ensuring that the orthogonal polarization isolation is not affected by routing and deteriorates. The routing of the microstrip transmission line 90 comprises two ways as shown in FIG. 1 and FIG. 2 .

In an embodiment, the microstrip transmission line 90 is a CPW transmission line. That is to say, both the first WI-FI antenna and the second WI-FI antenna are connected to the circuit module through the CPW transmission line, so as to realize the data transmission of the WI-FI antennas 30.

In an embodiment, the BLUETOOTH antenna 20 is a microstrip BLUETOOTH antenna and has a radiation slit. Specifically, the microstrip BLUETOOTH antenna has only one radiation slit. Further, a length of the radiation slit can be particularly lengthened, so that the length of the radiation slit is greater than a half of a wavelength of a medium.

Further, the WI-FI antennas 30 are arranged as the current source vertical polarization antennas; the substrate 10 is an FR4 substrate. Preferably, the substrate 10 adopts a low-loss high-frequency board FR4 base material.

The present disclosure realizes the orthogonal polarization by using the antennas with the different radiation sources, thereby realizing the polarization isolation, and arranges the RF ground of the magnetic current source between the WI-FI antennas to realize the isolation between the WI-FI antennas, and does not need to completely utilize spatial isolation and meets the requirement of the module miniaturization. By the isolation method of the present disclosure, the isolation degree of the WI-FI antennas can reach −16 dB, and the isolation degree between the WI-FI and BT antennas can reach more than −40 dB, as shown in FIG. 3 . The WI-FI antennas achieve omnidirectional horizontal radiation as shown in FIG. 4 , and a radiation diagram of the BT antenna is shown in FIG. 5 , and forward gain and reverse gain exceed −10 dB. Voltage standing wave ratio (VSWR) characteristics of the three antennas are shown in FIG. 6 . Therefore, the forward gain is significantly improved, the WI-FI antennas achieve omnidirectional no-blind area in a horizontal plane, transmission is smooth, and a throughput rate is approximately doubled in all directions. Therefore, the present disclosure improves the isolation degree between the antennas under a condition of multiple antennas, thereby improving the throughput rate of WI-FI and an electromagnetic compatibility of BT & WIFI.

In summary, the signal transmission apparatus provided in the present disclosure comprises: the substrate, and the BLUETOOTH antenna and the WI-FI antennas which are provided on the same side edge of the substrate. At least two branches of the WI-FI antennas are provided, and the BLUETOOTH antenna and the WI-FI antennas are provided at intervals. According to the present disclosure, the BLUETOOTH antenna and the WI-FI antennas are provided on the same side edge of the substrate, and the BLUETOOTH antenna and the WI-FI antennas are provided at intervals, so that all the antennas of the signal transmission apparatus are provided at the edge of the terminal board, thereby facilitating signal transmission, and solving the problem in the prior art that the BLUETOOTH antenna and the WI-FI antennas are respectively provided on two side edges of the substrate, affecting the data transmission.

It should be understood that the application of the present disclosure is not limited to the above examples, and those of ordinary skill in the art can make improvements or transformations according to the above descriptions, and all these improvements and transformations should fall within the protection scope of the appended claims of the present disclosure. 

What is claimed is:
 1. A signal transmission apparatus, comprising: a substrate; and a BLUETOOTH antenna and WIFI antennas which are provided on a same side edge of the substrate; at least two branches of the WIFI antennas are provided, and the BLUETOOTH antenna and the WIFI antennas are provided at intervals.
 2. The signal transmission apparatus as claimed in claim 1, wherein the BLUETOOTH antenna is a magnetic current source BLUETOOTH antenna, and the WIFI antenna is a current source WIFI antenna.
 3. The signal transmission apparatus as claimed in claim 1, wherein the WIFI antennas are configured to two branches, which are a first WIFI antenna and a second WIFI antenna, and the BLUETOOTH antenna is arranged between the first WIFI antenna and the second WIFI antenna.
 4. The signal transmission apparatus as claimed in claim 3, wherein the substrate is provided with a circuit ground, a first WIFI antenna RF ground, and a second WIFI antenna RF ground, the BLUETOOTH antenna is arranged on the circuit ground, the first WIFI antenna is arranged on the first WIFI antenna RF ground, and the second WIFI antenna is arranged on the second WIFI antenna RF ground.
 5. The signal transmission apparatus as claimed in claim 4, wherein a first dividing slit is defined between the circuit ground and the first WIFI antenna RF ground, and a second dividing slit is defined between the circuit ground and the second WIFI antenna RF ground.
 6. The signal transmission apparatus as claimed in claim 5, wherein, widths of the first dividing slit and the second dividing slit are greater than or equal to 0.1 mm.
 7. The signal transmission apparatus as claimed in claim 6, wherein microstrip transmission lines are arranged in the substrate, a circuit module is arranged on the circuit ground, both the first WIFI antenna and the second WIFI antenna are connected to the circuit module through the microstrip transmission lines.
 8. The signal transmission apparatus as claimed in claim 7, wherein a routing mode of the microstrip transmission line is vertical routing or parallel routing.
 9. The signal transmission apparatus as claimed in claim 2, wherein the magnetic current source BLUETOOTH antenna is a microstrip magnetic current source BLUETOOTH antenna and has a radiation slit.
 10. The signal transmission apparatus as claimed in claim 1, wherein the WIFI antenna is configured as a vertical polarization antenna.
 11. The signal transmission apparatus as claimed in claim 1, wherein the substrate is an FR4 substrate.
 12. The signal transmission apparatus as claimed in claim 1, wherein the substrate is a hollow cuboid, and the BLUETOOTH antenna and the WIFI antennas are arranged in the substrate and are close to a same long side edge.
 13. The signal transmission apparatus as claimed in claim 6, wherein the widths of the first dividing slit and the second dividing slit are both configured to be 1 mm.
 14. The signal transmission apparatus as claimed in claim 7, wherein the microstrip transmission line is a CPW transmission line.
 15. The signal transmission apparatus as claimed in claim 5, wherein the first dividing slit and the second dividing slit are formed by etching slits.
 16. The signal transmission apparatus as claimed in claim 9, wherein a length of the radiation slit is greater than half of a wavelength of a medium. 